configs/topologies/MeshDirCorners_XY.py - testing/jenkins-gem5-prod - Git at Google

 # Copyright (c) 2010 Advanced Micro Devices, Inc.
 # All rights reserved.
 #
 # Redistribution and use in source and binary forms, with or without
 # modification, are permitted provided that the following conditions are
 # met: redistributions of source code must retain the above copyright
 # notice, this list of conditions and the following disclaimer;
 # redistributions in binary form must reproduce the above copyright
 # notice, this list of conditions and the following disclaimer in the
 # documentation and/or other materials provided with the distribution;
 # neither the name of the copyright holders nor the names of its
 # contributors may be used to endorse or promote products derived from
 # this software without specific prior written permission.
 #
 # THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
 # "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
 # LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
 # A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
 # OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 # SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
 # LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
 # DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
 # THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
 # (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
 # OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 #
 # Authors: Brad Beckmann

 from __future__ import print_function
 from __future__ import absolute_import

 from m5.params import *
 from m5.objects import *

 from .BaseTopology import SimpleTopology

 # Creates a Mesh topology with 4 directories, one at each corner.
 # One L1 (and L2, depending on the protocol) are connected to each router.
 # XY routing is enforced (using link weights) to guarantee deadlock freedom.

 class MeshDirCorners_XY(SimpleTopology):
     description='MeshDirCorners_XY'

     def __init__(self, controllers):
         self.nodes = controllers

     def makeTopology(self, options, network, IntLink, ExtLink, Router):
         nodes = self.nodes

         num_routers = options.num_cpus
         num_rows = options.mesh_rows

         # default values for link latency and router latency.
         # Can be over-ridden on a per link/router basis
         link_latency = options.link_latency # used by simple and garnet
         router_latency = options.router_latency # only used by garnet


         # First determine which nodes are cache cntrls vs. dirs vs. dma
         cache_nodes = []
         dir_nodes = []
         dma_nodes = []
         for node in nodes:
             if node.type == 'L1Cache_Controller' or \
             node.type == 'L2Cache_Controller':
                 cache_nodes.append(node)
             elif node.type == 'Directory_Controller':
                 dir_nodes.append(node)
             elif node.type == 'DMA_Controller':
                 dma_nodes.append(node)

         # Obviously the number or rows must be <= the number of routers
         # and evenly divisible.  Also the number of caches must be a
         # multiple of the number of routers and the number of directories
         # must be four.
         assert(num_rows > 0 and num_rows <= num_routers)
         num_columns = int(num_routers / num_rows)
         assert(num_columns * num_rows == num_routers)
         caches_per_router, remainder = divmod(len(cache_nodes), num_routers)
         assert(remainder == 0)
         assert(len(dir_nodes) == 4)

         # Create the routers in the mesh
         routers = [Router(router_id=i, latency = router_latency) \
             for i in range(num_routers)]
         network.routers = routers

         # link counter to set unique link ids
         link_count = 0

         # Connect each cache controller to the appropriate router
         ext_links = []
         for (i, n) in enumerate(cache_nodes):
             cntrl_level, router_id = divmod(i, num_routers)
             assert(cntrl_level < caches_per_router)
             ext_links.append(ExtLink(link_id=link_count, ext_node=n,
                                     int_node=routers[router_id],
                                     latency = link_latency))
             link_count += 1

         # Connect the dir nodes to the corners.
         ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[0],
                                 int_node=routers[0],
                                 latency = link_latency))
         link_count += 1
         ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[1],
                                 int_node=routers[num_columns - 1],
                                 latency = link_latency))
         link_count += 1
         ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[2],
                                 int_node=routers[num_routers - num_columns],
                                 latency = link_latency))
         link_count += 1
         ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[3],
                                 int_node=routers[num_routers - 1],
                                 latency = link_latency))
         link_count += 1

         # Connect the dma nodes to router 0.  These should only be DMA nodes.
         for (i, node) in enumerate(dma_nodes):
             assert(node.type == 'DMA_Controller')
             ext_links.append(ExtLink(link_id=link_count, ext_node=node,
                                      int_node=routers[0],
                                      latency = link_latency))

         network.ext_links = ext_links

         # Create the mesh links.
         int_links = []

         # East output to West input links (weight = 1)
         for row in range(num_rows):
             for col in range(num_columns):
                 if (col + 1 < num_columns):
                     east_out = col + (row * num_columns)
                     west_in = (col + 1) + (row * num_columns)
                     int_links.append(IntLink(link_id=link_count,
                                              src_node=routers[east_out],
                                              dst_node=routers[west_in],
                                              src_outport="East",
                                              dst_inport="West",
                                              latency = link_latency,
                                              weight=1))
                     link_count += 1

         # West output to East input links (weight = 1)
         for row in range(num_rows):
             for col in range(num_columns):
                 if (col + 1 < num_columns):
                     east_in = col + (row * num_columns)
                     west_out = (col + 1) + (row * num_columns)
                     int_links.append(IntLink(link_id=link_count,
                                              src_node=routers[west_out],
                                              dst_node=routers[east_in],
                                              src_outport="West",
                                              dst_inport="East",
                                              latency = link_latency,
                                              weight=1))
                     link_count += 1

         # North output to South input links (weight = 2)
         for col in range(num_columns):
             for row in range(num_rows):
                 if (row + 1 < num_rows):
                     north_out = col + (row * num_columns)
                     south_in = col + ((row + 1) * num_columns)
                     int_links.append(IntLink(link_id=link_count,
                                              src_node=routers[north_out],
                                              dst_node=routers[south_in],
                                              src_outport="North",
                                              dst_inport="South",
                                              latency = link_latency,
                                              weight=2))
                     link_count += 1

         # South output to North input links (weight = 2)
         for col in range(num_columns):
             for row in range(num_rows):
                 if (row + 1 < num_rows):
                     north_in = col + (row * num_columns)
                     south_out = col + ((row + 1) * num_columns)
                     int_links.append(IntLink(link_id=link_count,
                                              src_node=routers[south_out],
                                              dst_node=routers[north_in],
                                              src_outport="South",
                                              dst_inport="North",
                                              latency = link_latency,
                                              weight=2))
                     link_count += 1


         network.int_links = int_links
	# Copyright (c) 2010 Advanced Micro Devices, Inc.
	# All rights reserved.
	#
	# Redistribution and use in source and binary forms, with or without
	# modification, are permitted provided that the following conditions are
	# met: redistributions of source code must retain the above copyright
	# notice, this list of conditions and the following disclaimer;
	# redistributions in binary form must reproduce the above copyright
	# notice, this list of conditions and the following disclaimer in the
	# documentation and/or other materials provided with the distribution;
	# neither the name of the copyright holders nor the names of its
	# contributors may be used to endorse or promote products derived from
	# this software without specific prior written permission.
	#
	# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
	# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
	# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
	# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
	# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
	# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	#
	# Authors: Brad Beckmann

	from __future__ import print_function
	from __future__ import absolute_import

	from m5.params import *
	from m5.objects import *

	from .BaseTopology import SimpleTopology

	# Creates a Mesh topology with 4 directories, one at each corner.
	# One L1 (and L2, depending on the protocol) are connected to each router.
	# XY routing is enforced (using link weights) to guarantee deadlock freedom.

	class MeshDirCorners_XY(SimpleTopology):
	description='MeshDirCorners_XY'

	def __init__(self, controllers):
	self.nodes = controllers

	def makeTopology(self, options, network, IntLink, ExtLink, Router):
	nodes = self.nodes

	num_routers = options.num_cpus
	num_rows = options.mesh_rows

	# default values for link latency and router latency.
	# Can be over-ridden on a per link/router basis
	link_latency = options.link_latency # used by simple and garnet
	router_latency = options.router_latency # only used by garnet


	# First determine which nodes are cache cntrls vs. dirs vs. dma
	cache_nodes = []
	dir_nodes = []
	dma_nodes = []
	for node in nodes:
	if node.type == 'L1Cache_Controller' or \
	node.type == 'L2Cache_Controller':
	cache_nodes.append(node)
	elif node.type == 'Directory_Controller':
	dir_nodes.append(node)
	elif node.type == 'DMA_Controller':
	dma_nodes.append(node)

	# Obviously the number or rows must be <= the number of routers
	# and evenly divisible. Also the number of caches must be a
	# multiple of the number of routers and the number of directories
	# must be four.
	assert(num_rows > 0 and num_rows <= num_routers)
	num_columns = int(num_routers / num_rows)
	assert(num_columns * num_rows == num_routers)
	caches_per_router, remainder = divmod(len(cache_nodes), num_routers)
	assert(remainder == 0)
	assert(len(dir_nodes) == 4)

	# Create the routers in the mesh
	routers = [Router(router_id=i, latency = router_latency) \
	for i in range(num_routers)]
	network.routers = routers

	# link counter to set unique link ids
	link_count = 0

	# Connect each cache controller to the appropriate router
	ext_links = []
	for (i, n) in enumerate(cache_nodes):
	cntrl_level, router_id = divmod(i, num_routers)
	assert(cntrl_level < caches_per_router)
	ext_links.append(ExtLink(link_id=link_count, ext_node=n,
	int_node=routers[router_id],
	latency = link_latency))
	link_count += 1

	# Connect the dir nodes to the corners.
	ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[0],
	int_node=routers[0],
	latency = link_latency))
	link_count += 1
	ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[1],
	int_node=routers[num_columns - 1],
	latency = link_latency))
	link_count += 1
	ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[2],
	int_node=routers[num_routers - num_columns],
	latency = link_latency))
	link_count += 1
	ext_links.append(ExtLink(link_id=link_count, ext_node=dir_nodes[3],
	int_node=routers[num_routers - 1],
	latency = link_latency))
	link_count += 1

	# Connect the dma nodes to router 0. These should only be DMA nodes.
	for (i, node) in enumerate(dma_nodes):
	assert(node.type == 'DMA_Controller')
	ext_links.append(ExtLink(link_id=link_count, ext_node=node,
	int_node=routers[0],
	latency = link_latency))

	network.ext_links = ext_links

	# Create the mesh links.
	int_links = []

	# East output to West input links (weight = 1)
	for row in range(num_rows):
	for col in range(num_columns):
	if (col + 1 < num_columns):
	east_out = col + (row * num_columns)
	west_in = (col + 1) + (row * num_columns)
	int_links.append(IntLink(link_id=link_count,
	src_node=routers[east_out],
	dst_node=routers[west_in],
	src_outport="East",
	dst_inport="West",
	latency = link_latency,
	weight=1))
	link_count += 1

	# West output to East input links (weight = 1)
	for row in range(num_rows):
	for col in range(num_columns):
	if (col + 1 < num_columns):
	east_in = col + (row * num_columns)
	west_out = (col + 1) + (row * num_columns)
	int_links.append(IntLink(link_id=link_count,
	src_node=routers[west_out],
	dst_node=routers[east_in],
	src_outport="West",
	dst_inport="East",
	latency = link_latency,
	weight=1))
	link_count += 1

	# North output to South input links (weight = 2)
	for col in range(num_columns):
	for row in range(num_rows):
	if (row + 1 < num_rows):
	north_out = col + (row * num_columns)
	south_in = col + ((row + 1) * num_columns)
	int_links.append(IntLink(link_id=link_count,
	src_node=routers[north_out],
	dst_node=routers[south_in],
	src_outport="North",
	dst_inport="South",
	latency = link_latency,
	weight=2))
	link_count += 1

	# South output to North input links (weight = 2)
	for col in range(num_columns):
	for row in range(num_rows):
	if (row + 1 < num_rows):
	north_in = col + (row * num_columns)
	south_out = col + ((row + 1) * num_columns)
	int_links.append(IntLink(link_id=link_count,
	src_node=routers[south_out],
	dst_node=routers[north_in],
	src_outport="South",
	dst_inport="North",
	latency = link_latency,
	weight=2))
	link_count += 1


	network.int_links = int_links